201005612 . 九、發明說明: 【發明所屬之技術領域】 種觸摸式便 本發明涉及一種便携式電腦,尤其涉及一 携式電腦。 【先前技術】 近年來,伴隨著移動電話與觸摸導航系統等各種電子 設備的高性能化和多樣化的發展,在液晶等顯示設備的前 面安裝透光性的觸摸屏的電子設備逐步增加。電子設備的 ❹使用者通過觸摸屏,一邊對位於觸摸屏背面的顯示設備的 顯示内容進行視覺確認,一邊利用手指或筆等方式按壓觸 摸屏來進行操作。由此,可以操作電子設備的各種功能。 先前技術中的便携式電腦通常將液晶顯示屏和電腦主 機連爲一體,且在液晶顯示屏的一個表面上設置有至少一 個觸摸屏,該觸摸屏可用作信號輸入裝置,來代替鼠標和 鍵盤用於信號的輸入,從而控制所述便携式電腦的各種功 此的開啓和關閉,以及文字的輸入。所述觸摸屏可根據其 工作原理和傳輸介質的不同,通常分爲四種類型,分別爲 電阻式、電容感應式、紅外線式以及表面聲波式。其中電 阻式觸摸屏和電容式觸摸屏由於其具有高解析度、高靈敏 度及耐用等優點,被廣泛應用在便携式電腦中。 然而’先前技術中的電容式和電阻式觸摸屏通常包括 一個作爲透明導電層的銦錫氧化物層(IT〇層),其採用離 子束賤射或 >賤鍵4工藝製備,Kazuhiro Noda等在文獻 Production of Transparent Conductive Films with Inserted 201005612201005612. IX. INSTRUCTIONS: TECHNICAL FIELD OF THE INVENTION The present invention relates to a portable computer, and more particularly to a portable computer. [Prior Art] In recent years, with the development of high performance and diversification of various electronic devices such as mobile phones and touch navigation systems, electronic devices in which a translucent touch panel is mounted on the front surface of a display device such as a liquid crystal are gradually increasing. The user of the electronic device visually confirms the display content of the display device located on the back of the touch screen through the touch screen, and presses the touch panel with a finger or a pen to operate. Thereby, various functions of the electronic device can be operated. The portable computer in the prior art usually integrates the liquid crystal display and the computer main body, and at least one touch screen is disposed on one surface of the liquid crystal display, and the touch screen can be used as a signal input device instead of a mouse and a keyboard for signals. The input, thereby controlling the various functions of the portable computer to turn on and off, and the input of text. The touch screen can be generally divided into four types according to the working principle and the transmission medium, which are resistive, capacitive inductive, infrared, and surface acoustic wave. Among them, resistive touch screens and capacitive touch screens are widely used in portable computers due to their high resolution, high sensitivity and durability. However, the capacitive and resistive touch screens of the prior art typically include an indium tin oxide layer (IT layer) as a transparent conductive layer, which is prepared by ion beam sputtering or > 贱 bond 4 process, Kazuhiro Noda et al. Literature of Transparent Conductive Films with Inserted 201005612
.Si02 Anchor Layer, and Application to a Resistive Touch Panel ( Electronics and Communications in Japan, Part 2, Vol.84,P39-45(2001))中介紹了一 種採用 IT〇/Si〇2/pET 層的觸摸屏。該ITO層作在製備的過程,需要較高的真空 環境及需要加熱到200〜30CTC,因此,使得汀〇声的製 成本較高。此外,先前技術中的ΙΤ〇層作爲透明導電層具 有機械性能不够好、難以彎曲及阻值分布不均勻等缺點。 另外,ΙΤΟ在潮濕的空氣中透明度會逐漸下降。從而導致 ®先削的觸摸屏及使用該觸摸屏的便携式電腦存在耐用性不 够好,靈敏度低、線性及準確性較差等缺點。 有鑒於此,提供一種採用觸摸屏的便携式電腦實為必 要該便携式電腦具有耐用性好、靈敏度高、線性及準確 性强的優點。 【發明内容】 一 一種便携式電腦,其包括:一顯示屏,該顯示屏具有 ❹:顯示面;一電腦主機,該電腦主機設置於所述顯示屏遠 顯示面的表面;以及至少一觸摸屏,該觸摸屏設置於所 =7F屏的顯示面’其中’所述觸摸屏爲採用奈米碳管作 透明導電層的觸摸屏。 0技相較於先前技術,本技術方案實施例提供的採用奈米 及S層作爲觸摸屏的透明導電層的便携式電腦具有以 黑占 · 甘 八、一,由於採用奈米碳管的觸摸屏可直接輸入操作命 ^和文字數據’從而可代替傳統的鍵盤和鼠標等輸入設 備’簡化了所述便携式電腦的結構,降低了厚度,從而使 7 201005612 .得所述便携式電腦携帶更方便。其二,由於奈米碳管在潮 •濕的條件下具有良好的透明度,故採用奈米碳管層作爲觸 摸屏的透明導電層,可以使該觸摸屏具有較好的透明度, 進而有利於提高使用該觸摸屏的便携式電腦的解析度。其 一由於奈米碳管具有優異的力學性能,則由奈末碳管組 成=米碳管層具有較好的勒性及機械强度,故採用該奈 米炭g層作爲觸摸屏的透明導電層,可以相應的提高觸摸 屏的耐用性,進而提高使用該觸摸屏的便携式電腦的耐用 丨μ 、四由於奈米碳管具有優異的導電性能,則由奈米 笞、、’成的不米碳官層具有均勻的阻值分布,因而,採用 紘Γ:米石厌管層作透明導電層’可以相應的提高觸摸屏的 斤:和精確度,進而提高應用該觸摸屏的便携式電腦的 解析度和精確度。 【實施方式】 ^ 、、、’σ &附圖詳細說明本技術方案實施例提供的便 携式電腦。 r 參^圖1 ’本技術方案第—實施例提供一便携式電 1Π α、,、 ’一顯不屏8〇、一電腦主機90及一觸摸屏 10。所述顯示屏罝古 _ m从 '、有顯不面801,所述電腦主機90設 置於所述顯示屏80读拙:Ηκ 1n ^ 屏80遠離顯示面δ〇ι的表面,所述觸摸屏 a .. _ ’’、屏80的顯示面801上。所述顯示屏80A touch screen using the IT〇/Si〇2/pET layer is described in Si02 Anchor Layer, and Application to a Resistive Touch Panel (Electronic and Communications in Japan, Part 2, Vol. 84, P39-45 (2001)). The ITO layer is used in the preparation process, requires a high vacuum environment and needs to be heated to 200 to 30 CTC, thus making the production cost of Tingsheng sound higher. In addition, the prior art germanium layer as a transparent conductive layer has disadvantages such as insufficient mechanical properties, difficulty in bending, and uneven distribution of resistance. In addition, the transparency of the cockroach will gradually decrease in the moist air. As a result, the touch screen that is first cut and the portable computer that uses the touch screen have disadvantages such as low durability, low sensitivity, linearity, and poor accuracy. In view of this, it is necessary for a portable computer using a touch screen to have the advantages of durability, sensitivity, linearity, and accuracy. SUMMARY OF THE INVENTION A portable computer includes: a display screen having a display surface; a computer main body disposed on a surface of the far display surface of the display screen; and at least one touch screen, The touch screen is disposed on the display surface of the =7F screen, wherein the touch screen is a touch screen using a carbon nanotube as a transparent conductive layer. Compared with the prior art, the portable computer using the nano- and S-layer as the transparent conductive layer of the touch screen provided by the embodiment of the present technical solution has a black-and-white, one-to-one, and can be directly used due to the touch screen using a carbon nanotube. The input operation and text data 'and thus can replace the traditional keyboard and mouse input device' simplifies the structure of the portable computer and reduces the thickness, so that the portable computer is more convenient to carry. Second, since the carbon nanotubes have good transparency under wet and wet conditions, the use of a carbon nanotube layer as a transparent conductive layer of the touch screen can make the touch screen have better transparency, thereby facilitating the use of the carbon nanotube. The resolution of the touch screen of the laptop. Because of the excellent mechanical properties of the carbon nanotubes, the composition of the carbon nanotubes = carbon nanotubes has good properties and mechanical strength, so the nano-carbon layer can be used as a transparent conductive layer of the touch screen. Correspondingly, the durability of the touch screen is improved, thereby improving the durability of the portable computer using the touch screen. 4. Because of the excellent electrical conductivity of the carbon nanotube, the nano-carbon layer of the nano-carbon layer is uniform. The resistance distribution, therefore, the use of 纮Γ: pebbles anodic layer as a transparent conductive layer' can correspondingly improve the touch screen: and accuracy, thereby improving the resolution and accuracy of the portable computer using the touch screen. [Embodiment] ^, ,, 'σ & The figure illustrates in detail a portable computer provided by an embodiment of the present technical solution. r 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 The display screen is 'm, and the computer host 90 is disposed on the display screen 80: Ηκ 1n ^ The screen 80 is away from the surface of the display surface δ〇ι, the touch screen a .. _ '', on the display surface 801 of the screen 80. The display screen 80
4液晶顯示屝、pB -e ^ 琢發射顯示屏、電漿顯示屏、電致發光顯 ::播1空:光顯示屏中的-種。該顯示屏80用於顯示電 〗出的數據和圖像。本實施例中,所述的顯示屏 8 201005612 .80爲一液晶顯示屏。由於所述顯示屏8〇、電腦主機卯及 .觸摸屏10爲一體設置,故,顯示屏80、電腦主機90及觸 摸屏10之間相互的電連接可通過内置的輸出端口(未標 不)或/和輸入端口(未標示)實現。本實施例中,觸摸屏 10的彳§號輸出端口通過内置的輸入端口與電腦主機9〇電 連接,顯示屏80通過輸出端口與電腦主機9〇電連接。 另外,爲了方便使用者更好地使用所述的便携式電腦 100,還可在所述便携式電腦1〇〇的電腦主機9〇的侧面設 ❹置至少一個外置的輸入端口 60和至少一個外置的輸出端 口 70,用於將外接鼠標和/或鍵盤與電腦主機連接起 來,從而實現另一種對電腦主機9〇的信號的輸入。 所述電腦主機90包括主板、中央處理器(cpu)、内存 及硬盤等αρ件。主板擁有系統總線、數據總線、控制總線、 多種插槽、接口等部件。CPU、内存、顯卡、聲卡、網卡、 視頻卡等安插在主板上,安裝在電腦主機90内的硬盤、電 ❹2等部件與主板通過電纜線相互連接。顯卡的一端與其中 〃個内置的輸出端口電連接,從而實現將電腦主機9〇處理 ,的信號傳輸給顯示屏8Ge進—步地,還可將機箱按紐、 提不燈、電源開關、硬盤指示燈、電源燈等部件都插到主 板相應位置上。另’在電腦主機90的側面還可設置有兩個 揚聲器904及磁盤驅動裝置9〇2。 有兩個 7斤述觸摸屏10具有輸入信號的功能,用戶可用手指或 觸摸筆等在觸摸屏10上通過觸摸或按壓將信號輸入給電 '機0具體地,所述觸摸屏1〇的面積可與顯示屏8〇 9 201005612 .的顯示®謝的面積相同。具體地,可將觸㈣1〇通過黏 ,結劑黏結於所述顯示面801上。可以理解,當觸摸屏1〇 的面積小於所述顯示面801時,可在顯示面8〇1上設置多 個觸摸屏1G’以便於同時實;見不同的功能。可以理解,觸 摸屏10輸人的信號可以爲命令信號和文字信號,從而可代 替先前技術的便携式電腦中使用的鼠標和鍵盤。另,爲了 多樣化的輸入信息,還可在顯示屏80的顯示面801上顯示 一屏幕鍵盤802,從而可通過對觸摸屏1〇的觸摸直接輸入 ❹文字信息。 請參閱11 2及目3 ’本技術方案第一實施例提供了一 電阻式觸摸屏1Q,其包括—第—電極板12,—帛二電極板 14以及設置在第一電極板12與第二電極板14之間的多個 透明的點狀隔離物16。 ❹ 該電阻式觸摸屏10的第一電極板12包括一第一基體 120, 一第一導電層122以及兩個第一電極124。該第:基 體120爲平面結構,該第一導電層122與兩個第一電極^ 均投置在第一基體120的下表面。兩個第一電極124分別 平行於第二方向設置在第一導電層122或第二基體的 兩端並與第-導電層122電連接。該觸摸屏1()的第二電極 板14包括一第二基體140, 一第二導電層142以及兩個第 -電極144。該第二基體14〇爲平面結構,該第二導電層 142與兩個第二電# 144均設置在第二基體⑽的上表 面。兩個第二電極144分別平行於第一方向設置在第二導 電層142或第二基體140的兩端並與第二 201005612 接。該第—方向垂直於爷 與兩個第二電極144正即兩個第-電極124 140的下表面正對該噸 、[觸摸屏10的第二基體 解,觸摸屏則的顯示面_ 該顯示屏80的顯示面801上 表面通過黏結劑黏附於 與該顯示屏s通過熱壓的方式直接設置 开叫的顯不面8〇1相接合。 薄膜爲㈣的且具有—定柔軟度的 ❹ 的材料4擇爲玻:體石1物明如 樹脂等柔性材料二;央==:性材料或_ 該第-雷托”“ 基 要起支撑的作用。 電極124與該第二電極144的材料爲、石山 g薄膜或其他導電材料 *、、 ^ 中,該第其^: 導電性即可。本實施例 :該第-基體120材料爲聚醋膜 璃基板;-電極124與第:電極144爲奈爲玻 该奈米礙管薄膜的寬度均爲1微米〜1毫米/、&/、 ❹厚步地’該第二電極板14上表面外圍設置有一絕緣 曰一。上述的第一電極板12設置在該絕緣層^上,且該 第:電極板12的第—導電層122正對第二電極板14的第 一導電層142設置。上述多個透明點狀隔離物16設置在第 一電極板14❺第二導電| 142上,且該多個透明點狀隔離 物16彼此間隔設置。第一電極板12與第二電極板μ之間 的距離爲2〜1〇微米。該絕緣層18與點狀隔離物16均可 採用絕緣透明樹脂或其他絕緣透明材料製成。設置絕緣層 18與點狀隔離物16可使得第一電極板14與第二電極板12 11 201005612 電絕緣。可以理解,當電阻式觸摸屏10尺寸較小時,點狀 隔離物16爲可選擇的結構’只需確保第一電極板14與第 二電極板12電絕緣即可。 魯 另外該第f極板12上表面可設置一透明保護膜 126。所述透明保護膜126可以通過黏結劑直接黏結在透明 導電層124上,也可採用熱壓法,與第__電極板壓合在__ 起。該透明保護臈126可採用-層表面硬化處理、光滑防 刮的塑料層或樹脂層,該樹脂層可由苯丙環丁婦(bcb)、 聚醋以及丙烯酸樹脂等材料形成。本實施例中,形成該透 明保護膜126的材料爲聚對苯二甲酸乙二醇醋⑽τ),用 ::護::電極板12’提高耐用性。該透明保護膜126經 特殊工藝處理後,可用以提供一些附加功能,如可 眩光或降低反射。 導雷一 Γ層122與第二導電層142中的至少-個 J電層包括-奈米碳管層’該奈米碳管層包括多個均句分 布的奈米碳管,且上述的奈米碳管無序排列或有序排列。 2無序㈣的奈米碳管通過凡德瓦爾力相互纏繞、相互 ^且平行於奈米碳管層的表面。料有序㈣的奈米碳 ==個方向擇優取向排列。所述奈米碳管層 ^至>-個有序奈米碳管薄膜,該有序奈 f 官首尾相連擇優取向排列,且相鄰的 =間通過凡德瓦爾力緊密結合。所述有序奈米碳^包 括至>、兩個重叠設置的有序奈米碳管薄臈,相鄰的兩個有 12 201005612 .序奈米碳管薄臈中的奈米碳管具有一交又角度〇1,且〇度 度。 又 t 本實施例中,所述奈米碳管層爲一有序奈米碳管薄 膜,該奈米碳管薄膜中的奈米碳管擇優取向排列。所述奈 米碳管薄膜進一步包括多個奈米碳管束片段,每個奈米碳 管束片段具有大致相等的長度且每個奈米碳管 個相互平行的奈米碳管構成,奈米碳管束片段兩端通過凡 德瓦爾力相互連接。所述奈米碳管薄膜的厚度爲〇5奈米 ®〜100微米,寬度爲0.01厘米〜100厘米。所述奈米碳J包 括單壁奈米碳管、雙壁奈米碳管和多壁奈米碳管。所述單 壁不米碳管的直徑爲0.5奈米〜50奈米,雙壁奈米碳管的 直徑爲1奈米〜50奈米,多壁奈米碳管的直徑爲15奈米 〜50奈米。 本實施例中,所述奈米碳管層爲重叠設置的多層有序 奈米碳管薄膜,每層奈米碳管薄膜中的奈米碳管沿同一方 ❹向擇優取向排列。所述奈米碳管薄膜進一步包括多個奈米 ,管束片段,每個奈米碳管束片段具有大致相等的長^且 每個奈米碳管束片段由多個相互平行的奈米碳管構成,奈 米石反管束片段兩端通過凡德瓦爾力相互連接。具體的,所 述第一導電層122中的多層奈米碳管薄膜均沿第一方向重 叠設置,第二導電層142中的多層奈米碳管薄膜均沿第二 方向重叠設置。所述奈米碳管薄膜的厚度爲〇·5奈米〜 微米,寬度爲〇.〇1厘米〜1〇厘米。 進一步地,可在該觸摸屏1〇第二基體14〇的下表面 13 201005612 亡設置一屏蔽層22,進一步地,可在該屏蔽層22遠離第 ,基體140的表面上設置一鈍化層24,該鈍化層24可由 虱化矽、氧化矽等材料形成。該鈍化層24與顯示設備2〇 的正面間隔-間隙26設置。該純化層24作爲介電層使 用,且保護該顯示設備20不致於由於外力過大而損壞。 器參見圖4,所述觸摸屏1〇進一步包括一觸摸屏控制 1 . “觸摸屏控制器39用於控制和處理使用者觸摸的 =信^所述顯示屏8G進一步包括—顯示屏控制器心 *不屏控制盗82用於控制顯示屏8〇的數據輸人或輸出。 電阻體介紹本實施例所述的便携式電腦100通過 觸摸屏10的觸摸進行顯示的具體過程。 間4用Ϊ極;所述電阻式觸摸屏10的第一電極板12之 覺確…壓。使用⑽ 過觸摸物5。如手指或-邊通 以進行操作。第—電=壓^阻式觸摸屏ig第—電極板 使得按壓處51的第—導電> /第―基體i2G發生-曲, 導電廢θ 122與第二電極板14的第二 導電岸122第觸:成導通。所述觸摸屏控制器19測量第一 方向:的電厂 =向進上的二壓變化與第二導電層-第二 並將該觸確計算,將㈣換成觸點坐標, 之後,電腦主機9n机4立 > , 上 然後’將處理後的數據通過二 80的顯示屏控制器…置的輸出知口傳輸給顯示屏 ° ’從而顯示屏80能根據使用者出入 201005612 的數據進行相應地顯示。 請一並參閱圖5和圖6’爲本技術方案第二實施例提 供的一便携式電腦200,其包括一顯示屏ι8〇、一電腦主機 190及一電容式觸摸屏30。 菖顯不屏180與電容式觸摸屏30間隔一定距離設置 叫*可在電谷式觸摸屏30的屏蔽層35遠離基體32的一個 表面上設置一鈍化層104,該鈍化層104可由氮化矽、氧 化矽、苯並環丁烯、聚酯膜或丙烯酸樹脂。該鈍化層1〇4 β與顯示屏180的正面間隔一間隙ι〇6設置。具體地,在上 述的鈍化層104與顯示屏18〇之間設置兩個支撑體1〇8。 該鈍化層104作爲介電層使用,所述鈍化層1〇4與間隙1〇6 可保護顯示屏180不致於由於外力過大而損壞。 ¥顯示屏180與電容式觸摸屏3〇集成設置時,可將上 述的支撑體⑽直接除去,而將鈍化層1〇4直接設置在顯 :屏180的顯示面181上。即’上述的純化層ι〇4與顯示 屏180之間無間隙地接觸設置。 ,述便携式電腦肅與本技術方案第—實施例提供的 電腦_結構大體相同,其不同之處在於,所述觸 :屏爲-電容式觸摸屏30,其包括一基體%、一透 广-防護層36及至少兩個電極38。基體3 =面以及與第一表面321相對的第二表面322 :透明J 電層34设置在基體32的第一表面321上 小 ^極38分別設置在透明導電層34的每個角處或L邊上兩^ 、透明導電層34形成電連接’ Μ在相導電層34上形 15 201005612 成等電位面。防護層36可直接設置在透明導電芦 電極38上。 玲 人及 所述基體32爲—曲面型或平面型的結構。該基體32 由玻璃、石英、金剛石或塑料等硬性材料或柔性材^ 所述基體32主要起支撑的作用。 所述透明導電層34包括—奈米碳管層,該夺 包括多個均句分布的奈米碳管,且上述的奈米碳管4: ❹ ❹ 列或有序排列。所述無序排列的奈米碳管通過凡德瓦爾力 相互纏繞、相互㈣且平行於奈米碳管層的表面。所 序排列的!米碳管沿一個方向或多個方向擇優取向排列。 所述奈^碳管層包括至少—個有序奈米碳管薄膜,該有序 奈米碳管薄料過直餘伸—奈米碳管陣列獲得。上述 有序奈米碳管薄膜中的奈米碳管首尾相連擇優取向排列, 且相鄰的奈米碳管之間通過凡德瓦爾力緊密結合。所述有 序奈米碳管層包括至少兩個重叠設置的有序奈米碳管薄 膜’相鄰的兩個有序奈求碳管薄膜中的奈米碳管具有一交 叉角度α ’且〇度^^知度。 本實施例中,所述奈米碳管層爲一有序奈米碳管薄 膜’該奈米碳管薄膜中的奈米碳管沿同一方向擇優取向排 所述奈米石厌官薄膜進一步包括多個奈米碳管束片段, 母個奈米碳管束片段具有大致相等的長度且每個奈米碳管 束片段由多個相互平行的奈米碳管構成,奈米碳管束片段 兩端通過凡德瓦爾力相互連接。所述奈米礙管薄膜的厚度 爲0.5奈米〜100微米,寬度爲0.01厘米〜100厘米。所述 16 201005612 .,米碳管,括單壁奈米碳管、雙壁奈米碳管和多壁奈米碳 ,管。所述單壁奈米碳管的直徑爲0.5奈米〜5〇奈米^雔辟 奈米碳管的直徑爲ί奈米〜50奈米,多壁奈米碳管的^ 爲1.5奈米〜5G奈米。所述奈米碳管薄膜的厚度爲奈: 〜100微米,寬度爲0.01厘米〜1()厘米。 ·不” 可以理解’所述透明導電層34和基體32的形狀可以 根據觸摸屏30的觸摸區域的形狀進行選擇。例如觸摸屏 30的觸摸區域可爲具有一長度的長線形觸摸區域、三角带 ❹觸摸區域及矩形觸摸區域等。本實施例中,觸摸#3〇的觸 摸區域爲矩形觸摸區域。 對於矩形觸摸區域,透明導電層34和基體32的形狀 也可爲矩形。爲了在上述的透明導電層34上形成均勻的電 阻網絡,需在該透明導電層34的四個角處或四邊上分別形 個電極38。上述的四個電極38可由金屬材料或奈米 碳管薄膜形成。具體地,在本實施例中,基體32爲玻璃基 板’所述四個電極38爲由銀或銅等低電阻的導電金屬鍍層 或者金屬箔片組成的條狀電極38。上述電極38間隔設置 在上述的透明導電層34同一表面的四個邊上。可以理解, 上述的電極38也可以設置在透明導電層34的不同表面 上,其關鍵在於上述電極38的設置能使得在透明導電層 34上形成等電位面即可。本實施例中,所述電極%設置 在透明導電層34的遠離基體的一個表面上。所述電極% 可以採用濺射、電鍍、化學鍍等沈積方法直接形成在透明 導電層34上。另外,也可用銀膠等導電黏結劑將上述的四 17 201005612 •個電極38黏結在透明導電層34的—個表面上。 J 可以理解’所述的金屬電極38亦可設置於透明導電層 34與基體32之間,且與透明導電層%電連接,並不限於 上f的設置方式和黏結方式。只要能使上述的電極%與透 V電層34上之間形成電連接的方式都應在本發明的保 護範圍内。 ’' 進步地’爲了延長透明導電層34的使用壽命和限制 柄合在接觸點與透明導電層34之間的電容,可以在透明導 ❹電f 34和電極之上設置一透明的防護層%,防護層%可 由氮化石夕、氧化石夕、苯丙環丁烯(BCB)、聚醋膜或丙婦酸 樹脂等形成。該防制36具有一定的硬度,對透明導電層 24起,護作用。可以理解,還可通過特殊的卫藝處理,從 而使得防護層36具有以下功能,例如减小炫光、降低反射 等。 在本實施例中,在形成有電極38的透明導電層34上 參設置-二氧化石夕層用作防護層36,該防護層%的硬度達 到7H(H爲洛氏硬度賴中,卸除主試驗力後,在初試驗 力下壓痕殘留的深度)。可以理解,防護層36的硬度和厚 度可以根據需要進行選擇。所述防護層36可以通過黏結劑 直接黏結在透明導電層34上。 此外,爲了减小由顯示設備產生的電磁干擾,避免從 觸摸屏30發出的信號産生錯誤,還可在基體%的第二表 面322 ^設置一屏蔽層%。該屏蔽層%可由麵錫氧化物 (ιτο)薄膜、録錫氧化物(Ατ〇)薄膜或奈米碳管薄膜等 18 201005612 1它。該奈米碳管薄膜可以係定向排列的或 二=米碳管薄膜。本實施例中,該奈米碳管薄膜 薄膜::二,所述多個奈米破管在上述的奈米碳管 太本山,向排歹,卜其具體結構可與透明導電層34相同。該 管薄膜作爲電接地點’起到屏蔽的作用,從而使得 觸搞屏30能在無干擾的環境中工作。 另,所述觸摸屏30進—步包括一觸摸屏控制器%, 2摸屏控制器39用於控制和計算使用者觸摸的信息。所 〜’:屏180進一步包括一顯示屏控制器182,該顯示屏 控制器182用於控制顯示屏18〇的數據輸入或輸出。 以下將具體介紹本技術方案第二實施例所述的便携式 電腦200通過觸摸屏3()的觸摸進行顯示的具體過程。4 liquid crystal display 屝, pB - e ^ 琢 emission display, plasma display, electroluminescence display :: broadcast 1 empty: the light in the display. The display 80 is used to display the data and images that have been output. In this embodiment, the display screen 8 201005612 .80 is a liquid crystal display. Since the display screen 〇, the computer main 卯 and the touch screen 10 are integrally arranged, the electrical connection between the display screen 80, the computer main unit 90 and the touch screen 10 can be through the built-in output port (not marked) or / And input port (not labeled). In this embodiment, the output port of the touch screen 10 is electrically connected to the computer host 9 through a built-in input port, and the display screen 80 is electrically connected to the computer host 9 through the output port. In addition, in order to facilitate the user to better use the portable computer 100, at least one external input port 60 and at least one external device may be disposed on the side of the computer host 9A of the portable computer. The output port 70 is used to connect an external mouse and/or a keyboard to the host computer, thereby implementing another input of a signal to the computer host 9〇. The computer host 90 includes a motherboard, a central processing unit (CPU), a memory, and a hard disk. The motherboard has system bus, data bus, control bus, various slots, interfaces and other components. The CPU, the memory, the graphics card, the sound card, the network card, the video card, and the like are inserted on the motherboard, and the components such as the hard disk, the electric cable 2, and the like installed in the computer host 90 are connected to each other through the cable. One end of the graphics card is electrically connected to one of the built-in output ports, so that the signal processed by the computer host 9〇 is transmitted to the display screen 8Ge, and the chassis button, the light, the power switch, and the hard disk can also be The indicators, power lights and other components are plugged into the corresponding positions on the motherboard. Further, two speakers 904 and a disk drive unit 9〇2 may be disposed on the side of the computer main unit 90. There are two functions in which the touch screen 10 has an input signal, and the user can input a signal to the electric machine 0 by touch or pressing on the touch screen 10 with a finger or a touch pen or the like. Specifically, the area of the touch screen 1 can be compared with the display screen. 8〇9 201005612. The display® Xie area is the same. Specifically, the contact (tetra) 1 黏 can be adhered to the display surface 801 by adhesion. It can be understood that when the area of the touch screen 1 is smaller than the display surface 801, a plurality of touch screens 1G' can be disposed on the display surface 8〇1 to facilitate simultaneous display; see different functions. It can be understood that the signals input by the touch screen 10 can be command signals and text signals, thereby replacing the mouse and keyboard used in the prior art portable computers. In addition, for a variety of input information, an on-screen keyboard 802 can also be displayed on the display surface 801 of the display screen 80 so that the text information can be directly input by touching the touch screen 1〇. Please refer to 11 2 and 3 '. The first embodiment of the present invention provides a resistive touch screen 1Q including a first electrode plate 12, a second electrode plate 14 and a first electrode plate 12 and a second electrode. A plurality of transparent, point-like spacers 16 between the plates 14. The first electrode plate 12 of the resistive touch panel 10 includes a first substrate 120, a first conductive layer 122 and two first electrodes 124. The first substrate 120 is a planar structure, and the first conductive layer 122 and the two first electrodes are disposed on the lower surface of the first substrate 120. The two first electrodes 124 are disposed at both ends of the first conductive layer 122 or the second substrate in parallel with the second direction and are electrically connected to the first conductive layer 122. The second electrode plate 14 of the touch panel 1() includes a second substrate 140, a second conductive layer 142 and two first electrodes 144. The second substrate 14 is a planar structure, and the second conductive layer 142 and the two second electrodes #144 are disposed on the upper surface of the second substrate (10). The two second electrodes 144 are respectively disposed at both ends of the second conductive layer 142 or the second substrate 140 in parallel with the first direction and are connected to the second 201005612. The first direction is perpendicular to the two second electrodes 144, that is, the lower surfaces of the two first electrodes 124 140 are opposite to the ton, [the second substrate of the touch screen 10, the display surface of the touch screen _ the display screen 80 The upper surface of the display surface 801 is adhered by the adhesive to the display surface s which is directly connected to the display screen s by hot pressing. The material 4 of the film is (4) and has a softness of ❹. The material 4 is selected as glass: the body stone 1 is as flexible as the resin 2; the central ==: sex material or _ the first - Reto" The role. The material of the electrode 124 and the second electrode 144 may be the conductivity of the stone or other conductive material *, , ^. In this embodiment, the material of the first substrate 120 is a polyester film substrate; the electrode 124 and the electrode 144 are N., and the width of the film is 1 micrometer to 1 mm/, & An insulating layer is disposed on the periphery of the upper surface of the second electrode plate 14. The first electrode plate 12 is disposed on the insulating layer, and the first conductive layer 122 of the first electrode plate 12 is disposed opposite to the first conductive layer 142 of the second electrode plate 14. The plurality of transparent dot spacers 16 are disposed on the first electrode plate 14 ❺ the second conductive 142, and the plurality of transparent dot spacers 16 are spaced apart from each other. The distance between the first electrode plate 12 and the second electrode plate μ is 2 to 1 μm. Both the insulating layer 18 and the dot spacer 16 may be made of an insulating transparent resin or other insulating transparent material. The provision of the insulating layer 18 and the dot spacers 16 allows the first electrode plate 14 to be electrically insulated from the second electrode plates 12 11 201005612. It will be appreciated that when the size of the resistive touch screen 10 is small, the dot spacers 16 are of an alternative construction' simply ensuring that the first electrode plate 14 is electrically insulated from the second electrode plate 12. Further, a transparent protective film 126 may be disposed on the upper surface of the f-plate 12 . The transparent protective film 126 may be directly bonded to the transparent conductive layer 124 by a bonding agent, or may be pressed by the __electrode plate at a temperature of __. The transparent protective tape 126 may be a layer-hardened, smooth, scratch-resistant plastic layer or a resin layer which may be formed of a material such as bbb, polyester, or acrylic. In the present embodiment, the material for forming the transparent protective film 126 is polyethylene terephthalate (10) τ), and the durability of the electrode plate 12' is improved. The transparent protective film 126 can be used in a special process to provide additional functions such as glare or reflection reduction. At least one of the conductive layer 126 and the second conductive layer 142 includes a carbon nanotube layer, the carbon nanotube layer includes a plurality of carbon nanotubes having a uniform distribution, and the above-mentioned nano tube The carbon nanotubes are arranged in an orderly or ordered manner. 2 The disordered (four) carbon nanotubes are intertwined by van der Waals forces, mutually and parallel to the surface of the carbon nanotube layer. The orderly (four) nanocarbon == direction alignment. The carbon nanotube layer ^ to > - an ordered carbon nanotube film, the ordered naf is connected end to end in a preferred orientation, and the adjacent = is tightly bound by van der Waals force. The ordered nanocarbons include to > two overlapping ordered carbon nanotubes, and the adjacent two have 12 201005612. The carbon nanotubes in the thin carbon nanotubes have One intersection and the angle 〇1, and the degree of ambiguity. In this embodiment, the carbon nanotube layer is an ordered carbon nanotube film, and the carbon nanotubes in the carbon nanotube film are preferentially aligned. The carbon nanotube film further comprises a plurality of carbon nanotube bundle segments, each of the carbon nanotube bundle segments having substantially equal lengths and each of the carbon nanotubes being formed of mutually parallel carbon nanotubes, the carbon nanotube bundle Both ends of the segment are connected to each other by Van der Waals force. The carbon nanotube film has a thickness of 〇5 nm ® to 100 μm and a width of 0.01 cm to 100 cm. The nanocarbon J comprises a single-walled carbon nanotube, a double-walled carbon nanotube, and a multi-walled carbon nanotube. The single-walled carbon nanotubes have a diameter of 0.5 nm to 50 nm, the double-walled carbon nanotubes have a diameter of 1 nm to 50 nm, and the multi-walled carbon nanotubes have a diameter of 15 nm to 50 nm. Nano. In this embodiment, the carbon nanotube layer is a multi-layered ordered carbon nanotube film which is arranged in an overlapping manner, and the carbon nanotubes in each layer of the carbon nanotube film are arranged in a preferred orientation along the same direction. The carbon nanotube film further comprises a plurality of nano tube bundle segments, each of the carbon nanotube bundle segments having substantially equal lengths, and each of the carbon nanotube bundle segments is composed of a plurality of mutually parallel carbon nanotube tubes, The ends of the nanostone reverse tube bundle are connected to each other by van der Waals force. Specifically, the plurality of layers of the carbon nanotube film in the first conductive layer 122 are overlapped in the first direction, and the plurality of layers of the carbon nanotube film in the second conductive layer 142 are overlapped in the second direction. The carbon nanotube film has a thickness of 〇·5 nm to μm and a width of 〇.〇1 cm to 1 cm. Further, a shielding layer 22 may be disposed on the lower surface 13 201005612 of the second substrate 14A of the touch screen 1 . Further, a passivation layer 24 may be disposed on the surface of the shielding layer 22 away from the second substrate 140 . The passivation layer 24 may be formed of a material such as antimony telluride or antimony oxide. The passivation layer 24 is disposed adjacent to the front surface of the display device 2A-gap 26. The purification layer 24 is used as a dielectric layer, and the display device 20 is protected from damage due to excessive external force. Referring to FIG. 4, the touch screen 1 further includes a touch screen control. 1. The touch screen controller 39 is used to control and process the user's touch. The display screen 8G further includes a display controller controller. The control hacker 82 is used to control the data input or output of the display screen 8. The resistor body describes the specific process of displaying the portable computer 100 of the present embodiment through the touch of the touch screen 10. The drain is used for the middle 4; The first electrode plate 12 of the touch screen 10 is determined to be pressed. (10) The touch object 5 is used. The finger or the edge is operated to operate. The first-electrode=resistive touch screen ig-electrode plate makes the pressing portion 51 The first-conducting > /the-substrate i2G is generated-curved, and the conductive waste θ 122 is electrically connected to the second conductive bank 122 of the second electrode plate 14. The touch screen controller 19 measures the first direction: the power plant = the second pressure change to the second and the second conductive layer - the second and the touch calculation, the (four) is replaced by the contact coordinates, after which the computer host 9n machine 4 >, then 'will process the data Output through the display controller of the 280 The port is transmitted to the display screen °' so that the display screen 80 can be displayed correspondingly according to the data of the user entering and exiting 201005612. Please refer to FIG. 5 and FIG. 6 'a portable computer 200 provided by the second embodiment of the present technical solution, The utility model comprises a display screen, a computer host 190 and a capacitive touch screen 30. The display screen is disposed at a distance from the capacitive touch screen 30, and the shield layer 35 of the electric valley touch screen 30 is away from the base 32. A passivation layer 104 is disposed on the surface, and the passivation layer 104 may be made of tantalum nitride, hafnium oxide, benzocyclobutene, a polyester film or an acrylic resin. The passivation layer 1〇4 β is spaced apart from the front surface of the display screen 180. Specifically, two support bodies 1 〇 8 are disposed between the passivation layer 104 and the display screen 18 。. The passivation layer 104 is used as a dielectric layer, and the passivation layer 1 〇 4 and the gap 1 〇 6 The display screen 180 can be protected from damage due to excessive external force. When the display screen 180 is integrated with the capacitive touch screen 3〇, the above-mentioned support body (10) can be directly removed, and the passivation layer 1〇4 can be directly set in the display: Screen 180 display On the surface 181, that is, the above-mentioned purification layer ι 4 is placed in contact with the display screen 180 without gaps. The portable computer is substantially the same as the computer _ structure provided in the first embodiment of the present technical solution, and the difference is the same. The touch screen is a capacitive touch screen 30 comprising a substrate %, a transparent-protective layer 36 and at least two electrodes 38. The substrate 3 = face and a second surface 322 opposite the first surface 321 The transparent J electric layer 34 is disposed on the first surface 321 of the base 32. The small electrodes 38 are respectively disposed at each corner or the L side of the transparent conductive layer 34, and the transparent conductive layer 34 is electrically connected. The conductive layer 34 has a shape of 15 201005612 into an equipotential surface. The protective layer 36 can be disposed directly on the transparent conductive reed electrode 38. The person and the base body 32 are of a curved surface type or a flat type structure. The base 32 is mainly supported by a hard material such as glass, quartz, diamond or plastic or a flexible material. The transparent conductive layer 34 comprises a carbon nanotube layer comprising a plurality of carbon nanotubes having a uniform distribution, and the above-mentioned carbon nanotubes 4 are arranged in an ordered or ordered manner. The disordered array of carbon nanotubes are intertwined by van der Waals forces, mutually (four) and parallel to the surface of the carbon nanotube layer. Arranged in order! The carbon nanotubes are arranged in a preferred orientation in one direction or in multiple directions. The carbon nanotube layer comprises at least one ordered carbon nanotube film obtained by over-external-nanocarbon tube array. The carbon nanotubes in the ordered carbon nanotube film are arranged end to end in a preferred orientation, and the adjacent carbon nanotubes are closely coupled by van der Waals force. The ordered carbon nanotube layer comprises at least two overlapping ordered carbon nanotube films. The carbon nanotubes in the adjacent two ordered carbon nanotube films have an intersection angle α 'and Degree ^^ know. In this embodiment, the carbon nanotube layer is an ordered carbon nanotube film. The carbon nanotubes in the carbon nanotube film are preferentially oriented in the same direction. The nano-stone anomaly film further comprises a plurality of carbon nanotube bundle segments, the mother carbon nanotube bundle segments having substantially equal lengths and each of the carbon nanotube bundle segments being composed of a plurality of mutually parallel carbon nanotubes, and the carbon nanotube bundle segments are flanked by van der Waals Valli is connected to each other. The nano tube film has a thickness of from 0.5 nm to 100 μm and a width of from 0.01 cm to 100 cm. The 16 201005612 ., carbon nanotubes, including single-walled carbon nanotubes, double-walled carbon nanotubes, and multi-walled nanocarbon, tubes. The single-walled carbon nanotube has a diameter of 0.5 nm to 5 Å nanometers. The diameter of the carbon nanotubes is 奈Nylon~50 nm, and the multi-walled carbon nanotubes are 1.5 nm~ 5G nanometer. The carbon nanotube film has a thickness of naf: ~100 μm and a width of 0.01 cm to 1 (cm). It is understood that the shapes of the transparent conductive layer 34 and the base 32 may be selected according to the shape of the touch area of the touch screen 30. For example, the touch area of the touch screen 30 may be a long line touch area having a length, a V-belt touch The area and the rectangular touch area, etc. In this embodiment, the touch area of the touch #3〇 is a rectangular touch area. For the rectangular touch area, the shape of the transparent conductive layer 34 and the base 32 may also be rectangular. For the above transparent conductive layer A uniform resistor network is formed on 34, and electrodes 38 are respectively formed at four corners or four sides of the transparent conductive layer 34. The above four electrodes 38 may be formed of a metal material or a carbon nanotube film. Specifically, In the present embodiment, the base 32 is a glass substrate. The four electrodes 38 are strip electrodes 38 made of a low-resistance conductive metal plating such as silver or copper or a metal foil. The electrodes 38 are spaced apart from each other in the above-mentioned transparent conductive The layers 34 are on the four sides of the same surface. It will be understood that the electrodes 38 described above may also be disposed on different surfaces of the transparent conductive layer 34. The electrode 38 is disposed such that an equipotential surface is formed on the transparent conductive layer 34. In this embodiment, the electrode % is disposed on a surface of the transparent conductive layer 34 away from the substrate. A deposition method such as sputtering, electroplating, or electroless plating is directly formed on the transparent conductive layer 34. Alternatively, the above-mentioned four 17 201005612 electrodes 38 may be bonded to one surface of the transparent conductive layer 34 by a conductive adhesive such as silver paste. J can understand that the metal electrode 38 can also be disposed between the transparent conductive layer 34 and the base 32, and is electrically connected to the transparent conductive layer, and is not limited to the arrangement and bonding manner of the upper f. The manner in which the electrode % is electrically connected to the V-transferred layer 34 is within the scope of the present invention. ''Progressively' in order to extend the useful life of the transparent conductive layer 34 and limit the handle to the contact point and the transparent conductive The capacitance between the layers 34 can be provided with a transparent protective layer % on the transparent conductive electrode f 34 and the electrode, and the protective layer % can be nitrided, oxidized oxide, phenylcyclobutene (BCB), poly Formed by a film or a bupropion resin, etc. The film 36 has a certain hardness and acts as a protective layer for the transparent conductive layer 24. It can be understood that the protective layer 36 can also be subjected to special functions such as the protective layer 36, for example, for example, for example, The glare is reduced, the reflection is reduced, etc. In the present embodiment, a transparent layer of the conductive layer 34 on which the electrode 38 is formed is provided as a protective layer 36, and the hardness of the protective layer reaches 7H (H). For Rockwell hardness, the depth of the indentation remaining under the initial test force after the main test force is removed. It is understood that the hardness and thickness of the protective layer 36 can be selected as needed. The protective layer 36 can be bonded. The agent is directly bonded to the transparent conductive layer 34. Further, in order to reduce electromagnetic interference generated by the display device and to avoid errors in signals emitted from the touch screen 30, a shield layer % may be disposed on the second surface 322 of the substrate. The shielding layer % may be a tin oxide oxide film, a tin oxide film or a carbon nanotube film, etc. 18 201005612 1 . The carbon nanotube film can be oriented or PTFE film. In this embodiment, the carbon nanotube film is: Second, the plurality of nanotubes are in the above-mentioned carbon nanotubes, and the specific structure can be the same as that of the transparent conductive layer 34. The tube film acts as a shield for electrical grounding, allowing the touch screen 30 to operate in a non-interfering environment. In addition, the touch screen 30 further includes a touch screen controller %, and the touch screen controller 39 is used to control and calculate information touched by the user. The screen panel 180 further includes a display controller 182 for controlling the data input or output of the display screen 18A. The specific process of displaying the portable computer 200 according to the second embodiment of the present technical solution through the touch of the touch screen 3() will be specifically described below.
在使用時,透明導電層34上施加一預定電壓。電壓通 過電極38施加到透明導電層34上,從而在該透明導電層 34上形成等電位面。使用者—邊視覺確認在觸摸屏%後 面設置的顯示屏18G的顯示,—邊通過手指或筆等觸摸物 150按壓或接近觸摸屏%的防護層%進行操作時,觸摸 請與透明導電層34之間形成一輕合電容。對於高頻電 流來說’電容係直接㈣,於斜指從接觸點吸走了—部 分電流。這個電流分別從觸摸屏3〇上的電極中流出,並且 流經這四個電極的電流與手指到四角的距離成正比,觸摸 屏控制器39通過對這四個電流比例的精確計算,得出觸摸 點的位置。之後,觸摸屏控制器39將數字化的觸摸位置數 據通過内置的輸入端口傳送給電腦主機19〇;之後,電腦 19 201005612 ♦主機190對接受到的數據進行處理;然後,將處理後的數 .據通過内置的輸出端口傳輸給顯示屏嚮的顯示屏控制器 182’從而顯示屏18G能根據顯示屏控制器182接受的數據 進行顯示,從而使得使用者出入的數據在顯示屏⑽ 行相應地顯示。 本技術方案實施例提供的携式電腦採用含有奈 的觸摸屏,具有以下優點. 狄吕 ^ 其一,由於採用奈米碳管的觸 參 、屏可直接輸人操作命令和文字數據,從而 鍵盤和鼠標等輸入設備,内 旁得統的 間化了所述便携式電腦的結構, 降低了厚度,從而使得所述便携式電腦携帶更方便。其二, 由於奈米碳管在潮濕的條件下具有良好的透明度,故採用 奈米碳管層作爲觸摸屏的透明莲 ., 开刃遷明導電層,可以使該觸摸屏具 有較好的透明度’進而有利於接古 電腦解析度。其三,由於摸屏的便携式 、不米厌g具有優異的力學性能, 則由奈米碳管組成的奈米碳管層 ❹ 度,故採用該奈米碳管層作=握的,f生及機械强 B層作爲觸摸屏的透明導電層,可以 相應的提高觸摸屏的耐用性 進而耠咼使用該觸摸屏的便 =電:用性;其四,由於奈求碳管具有優異的導電 月匕,則由不米碳管組成的奈米碳管層具有均勻的阻值分 布^而,採用上述奈米碳管層作透明導電層,可以相應 的提尚觸摸屏的解析度和精確产 μ 的便携式電腦的解析度心=。進而“應用該觸摸屏 ,上所述,本發明確已符合發明專利之要件,遂依法 專利申請。惟,以上所述者僅為本發明之較佳實施例, 20 201005612 自不能以此限制本案之申請㈣範圍。舉 ^人士援依本發^精神所作之等效修飾或變化,皆應 盍於以下申請專利範圍内。 ‘ 【圖式簡單說明】 圖1係本技術方案第一實施例便携式電腦的結構示意 圖。 圖2係本技術方案第一實施例便携式電腦中的觸摸屏 的立體結構示意圖。 ❿ 圖3係本技術方案第一實施例便携式電腦中的觸摸屏 的側視結構示意圖。 圖4係本技術方案第一實施例便携式電腦工作示意 圖。 圖5係本技術方案第二實施例便携式電腦中的觸摸屏 的立體結構示意圖。 圖6係本技術方案第二實施例便携式電腦工作示意 圖。 21 201005612In use, a predetermined voltage is applied across the transparent conductive layer 34. A voltage is applied to the transparent conductive layer 34 through the electrode 38 to form an equipotential surface on the transparent conductive layer 34. The user visually confirms the display of the display screen 18G disposed behind the touch screen %, and when the user touches or approaches the protective layer % of the touch screen % by a finger or a pen, the touch is made between the transparent conductive layer 34 and the transparent conductive layer 34. Form a light combined capacitor. For high-frequency currents, the capacitance is directly (four), and the oblique finger is sucked away from the contact point—partial current. This current flows out from the electrodes on the touch screen 3〇, respectively, and the current flowing through the four electrodes is proportional to the distance from the finger to the four corners, and the touch screen controller 39 obtains the touch point by accurately calculating the ratio of the four currents. s position. Thereafter, the touch screen controller 39 transmits the digitized touch position data to the computer host 19 via the built-in input port; after that, the computer 19 201005612 ♦ the host 190 processes the received data; and then passes the processed number. The built-in output port is transmitted to the display controller 182' of the display screen so that the display 18G can be displayed according to the data accepted by the display controller 182, so that the user's incoming and outgoing data is displayed correspondingly on the display (10). The portable computer provided by the embodiment of the technical solution adopts a touch screen containing Nai, and has the following advantages. Di Lu ^ First, due to the use of the carbon nanotube touch parameter, the screen can directly input the operation command and the text data, thereby the keyboard and An input device such as a mouse intervenes to structure the portable computer, reducing the thickness, thereby making the portable computer more convenient to carry. Second, because the carbon nanotubes have good transparency under humid conditions, the carbon nanotube layer is used as the transparent lotus of the touch screen. The transparent conductive layer can be opened to make the touch screen have better transparency. Conducive to the ancient computer resolution. Thirdly, since the portable screen of the touch screen has excellent mechanical properties, the carbon nanotube layer composed of the carbon nanotubes has a twist, so the carbon nanotube layer is used as the grip, The mechanical strong B layer acts as a transparent conductive layer of the touch screen, which can correspondingly improve the durability of the touch screen, and then the use of the touch screen = electricity: usability; fourth, because the carbon tube has an excellent conductive moon, it is The carbon nanotube layer composed of the non-carbon tube has a uniform resistance distribution, and the above-mentioned carbon nanotube layer is used as the transparent conductive layer, which can correspondingly improve the resolution of the touch screen and the resolution of the portable computer with accurate μ production. Degree =. Further, "the application of the touch screen, the above description, the invention has indeed met the requirements of the invention patent, and the patent application according to law. However, the above is only a preferred embodiment of the present invention, 20 201005612 can not limit the case The scope of the application (4). The equivalent modifications or changes made by the person in accordance with the spirit of the present invention shall be within the scope of the following patent application. ' [Simple Description of the Drawings] FIG. 1 is a portable computer of the first embodiment of the technical solution. 2 is a schematic perspective view of a touch screen in a portable computer according to a first embodiment of the present invention. FIG. 3 is a side view showing a structure of a touch screen in a portable computer according to a first embodiment of the present technical solution. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 5 is a schematic perspective view of a touch screen in a portable computer according to a second embodiment of the present technical solution. FIG. 6 is a schematic view showing the operation of a portable computer according to a second embodiment of the present technical solution. 21 201005612
【主要元件符號說明】 便携式電腦 100, 200 輸入端口 60 觸摸屏 10 輸出端口 70 第一電極板 12 顯示屏 80, 180 第二電極板 14 顯示屏控制器 82, 182 點狀隔離物 16 電腦主機 90, 190 絕緣層 18 顯示面 801 第一基體 120 屏幕鍵盤 802 第一導電層 122 磁盤驅動裝置 902 第一電極 124 揚聲器 904 第二基體 140 屏蔽層 22, 35 第二導電層 142 鈍化層 24, 104 第二電極 144 間隙 26, 106 按壓處 51 觸摸屏控制器 19, 39 電容式觸摸屏 30 觸摸物 50, 150 基體 32 防護層 36 第一表面 321 電極 38 第二表面 322 顯示面 181 透明導電層 34 電腦主機 190 支撑體 108 22[Main component symbol description] Portable computer 100, 200 Input port 60 Touch screen 10 Output port 70 First electrode plate 12 Display 80, 180 Second electrode plate 14 Display controller 82, 182 point spacer 16 Computer host 90, 190 Insulation layer 18 Display surface 801 First substrate 120 Screen keyboard 802 First conductive layer 122 Disk drive device 902 First electrode 124 Speaker 904 Second substrate 140 Shield layer 22, 35 Second conductive layer 142 Passivation layer 24, 104 Second Electrode 144 Clearance 26, 106 Pressing point 51 Touch screen controller 19, 39 Capacitive touch screen 30 Touch object 50, 150 Base 32 Protective layer 36 First surface 321 Electrode 38 Second surface 322 Display surface 181 Transparent conductive layer 34 Computer host 190 Support Body 108 22